IT201800009370A1 - COGENERATOR OF ENERGY AND CRYPT-CURRENCY - Google Patents

Description

Patent Application for Industrial Invention under:

"COGENERATOR OF ENERGY AND CRYPT-CURRENCY"

Description

Field of application

The present invention finds application in the technical sector of information technology and fluid mechanics, it relates to a liquid-cooled computing hardware for the production of a hot fluid (e.g. water) and blocks of encrypted information with consequent remuneration in crypto currencies. (e.g. Bitcoin, Ethereum, etc.).

State of the art

Currently, mining operations (control, validation and cryptography of transactions in a block chain network, which is undergoing strong development especially in the field of crypto-currencies) are performed by dedicated, air-cooled computers, with a large calculation capacity and consequently important electricity consumption. The products generated by the hardware are nothing more than files, placed on the internet; it is therefore clear that the incoming energy flow is almost totally transformed into heat, usually disposed of (therefore dispersed) in the environment, through fans.

In countries where the cost of electricity is quite high, such as in Italy, the mining operation is sometimes inconvenient, since the remuneration received (in crypto-currencies) is lower than the cost of the energy used.

Another aspect concerns newly built photovoltaic systems (or other renewable source systems), which no longer enjoy particular incentives for the injection of electricity into the national grid; in addition to self-consumption, there is no other way to economically exploit the energy produced by these systems.

Accumulating and enhancing self-produced electricity (for a private individual or a company), to date, can be a problem.

Presentation of the invention

The purpose of the present invention is to exploit electricity to produce, on the one hand, blocks of controlled digital transactions, (for a block chain network for example), validated and encrypted; on the other hand, a hot fluid to be used for space heating, the production of hot water for sanitary use, water or hot process fluids, etc.

The process of processing the aforementioned digital transactions requires a great computing capacity, since it sees the resolution of complex algorithms. The data exchanged between the nodes of the network are in fact protected with cryptographic hash functions; for the resolution of these functions (i.e. processing transactions and collecting commissions) a search for the result by brute force is required. By brute force method we mean an algorithm for solving a problem that consists in trying all the theoretically possible solutions until finding the one that works.

It is not the purpose of this report to describe in detail a mining process, for which no innovation is brought. What we want to underline is that, for the execution of the calculation operations described, dedicated units are used, operating with a number n of processors in parallel, which require a constant and considerable electrical power commitment, also requiring a system of effective cooling.

The innovation sees the replacement of air cooling, made with radiators and fans that disperse the heat in the environment, with a liquid cooling that recovers the heat produced by the processors in the form of hot water (or other fluid) and accumulates it in a tank, allowing for intelligent use.

The present invention can be achieved by means of electrical and mechanical components already present on the market, the configuration of the system and the concept of cogeneration understood as the production of physical and digital goods constitute an invention.

Various criteria can be used to define the characteristics of the system, depending on the objectives to be achieved, namely:

a) profit through crypto-currencies;

b) production of a given power in the form of heat;

in case a) the computer hardware is sized according to the computing capacity required to achieve a certain profit target in terms of crypto-currencies (or in terms of data processing from other bock chains); in case b) it is sized according to the heat produced by the cooling system.

Once the calculation unit has been chosen, the motherboards are arranged with a layout that allows the liquid radiators (existing on the market) to be mounted on the processors. The radiators, placed in contact with the processors, have an inlet and an outlet for the refrigerant fluid; they are connected in parallel through a delivery and a return manifold. A circuit is then created which leads the cooling fluid to an accumulation of water (or other liquid), where the heat produced is released, through an exchanger. On leaving this exchanger, the cooling fluid is sent back to the processors.

Basically it is a classic closed loop circuit, where there is a heat generator (processors), and a user that removes thermal energy (storage); circulation is guaranteed by a pump.

In parallel to the accumulation heat exchanger, an air-cooled radiator is created, which constitutes the auxiliary cooling of the processors in the event that, for any reason, the accumulation must be excluded from the cooling circuit (e.g. if it is already hot).

They are secondary but functional components of the hydraulic circuit:

- valves mounted on the connection pipes for the interception of the various parts of the circuit;

- micrometric valves for hydraulic balancing of the circuit branches;

- maximum pressure safety valve;

- expansion tank to compensate for the increase in volume of the cooling fluid;

- vent valves for any air bubbles;

- pressure gauges for pressure control;

- thermometers for temperature control;

The connection is shown in figure FIG. 1, by way of non-limiting example.

At the service of the hydraulic circuit there is an electronic control unit which, through the temperature probes, manages the circulation of the fluid by controlling the pump and any diverter valve for auxiliary cooling, with the aim of keeping the temperature at the optimal level. of processors.

The thermal energy recovered through the system described can be used, for example, for space heating, the production of domestic hot water, the production of process water, etc.

A variant of the heat recovery system described is constituted by a R410A type refrigerant fluid heat exchange system. The innovative principle of cogeneration does not change, in this case, however, the hydraulic circuit is replaced with a refrigeration circuit. In correspondence with the processors there is space for the evaporator which proceeds to cool the computing units, at the accumulation the condenser which transfers heat to the liquid in the tank is created. The circuit is then completed with the minimum components necessary for the operation of the refrigeration cycle, by way of example: compressor, lamination valve, sensors and control.

The third variant of the heat exchange system between processors and accumulated fluid for heat recovery involves the use of heat pipes (or pulsating heat pipes). In this case, no other electrical devices (such as pumps or compressors) are required for heat transfer. The physical phenomenon for which the heat exchange between the sources is possible, without any other external energy input, is based solely on the changes in the state of evaporation (from liquid to gaseous) and condensation (from gaseous to liquid) of the refrigerant fluid inside the 'heat pipe. The evaporation section is placed in correspondence with the processors, while the condensation section is placed in contact with the fluid in the accumulation. When the computing hardware is started, with the heating of the processors, the heat exchange starts automatically.

If on the one hand there is the accumulation of thermal energy, on the other hand there is the processing of a huge amount of data, which are processed and simultaneously exchanged with the internet through a router. The operations that the mining hardware performs are planned by a control PC, on which there is software (existing on the market, sometimes open source) for the configuration of the miner processors. Once the block chain network to work on has been decided, the parameters set and the hardware started, the computer starts the so-called hash operations in brute force, to process encrypted transactions and thus obtain a remuneration. The calculation capacity is measured in Hash per second (H / s) and its multiples, it is therefore possible to estimate the relative amount of crypto-currency produced per day, convertible into Euro at the current exchange rate.

A specific application of the invention is identified in the power supply of the computing hardware through a photovoltaic system, directly or through an accumulation. No innovation is made regarding the solar system and its components, but the original idea is to exploit the current produced to power the computing hardware, produce crypto-currency (or treat other block chains) and heat. In this way, there is an alternative and profitable enhancement of the energy produced by the photovoltaic system, which is currently poorly paid for by placing it on the grid (for newly built plants), especially in Italy. An example of the connection of the photovoltaic modules to the proposed cogeneration system is shown in figure FIG.2.

From the description of the system, the achievement of the pre-established purpose is evident. The invention also introduces an innovative concept of poly-generation and the calculation of its performance, no longer based only on physical parameters, but also on the value of the information processed and produced.

Brief description of the drawings

Further features and advantages of the invention will become more evident in the light of the detailed description of a preferred but not exclusive embodiment, illustrated by way of non-limiting example with the help of the accompanying drawing figures in which:

- FIG. 1 which represents the hydraulic scheme of heat recovery from the processors;

- FIG. 2 which represents the basic electrical / electronic diagram according to which photovoltaic electricity is used to operate the hardware from which heat is recovered and through which the data is processed, then transmitted to the internet.

Detailed description of a preferred example of embodiment With reference to the attached figures, an example of embodiment of the cogenerator is shown.

For the construction of the system it is possible to use apparatuses, devices and materials already on the market. In this case, it was decided to create a system based on computing hardware (1.1) consisting of 3 motherboards (1.7) on which 18 processors (1.8) are distributed, for a computing capacity of about 200 MH / s and a power electricity required by the 800 W power supply (2.3). This is an ASIC (application specific integrated circuits) device on the market, designed to mine the Ethereum crypto-currency, specially modified to replace the air cooling system, a system with liquid, through the exchangers placed in contact with the processors.

The data exchange system with the internet takes place through a motherboard interface (2.5) and a router (2.6); the entire ASIC system is configured through a PC (2.7) with dedicated software installed. Figure FIG.2 identifies: the electrical power network (2.11), the control network (2.10) and the data network (2.12).

The photovoltaic system for the production of electricity (2.1) was designed to power the hardware 24 hours a day; to generate and store the 19.2 kWh of electricity required in a battery (2.2), an approximately 5 kWp plant is needed in an area of northern Italy; the current is stored in a battery.

The hydraulic heat exchange circuit consists of 18 heat exchangers (1.9) in contact with the processors; the delivery and return network is made with metal or plastic pipes (1.12 -1.13), as well as the valves. Circulation is guaranteed by a pump (1.4) with a power of about 20 W which allows the exchange fluid to transport the heat produced by the electronics, in the accumulation of recovery water (1.2).

In parallel to the heat exchanger of the storage tank (1.10), an air-cooled radiator (1.3) is connected to remove heat from the processors in the event that heat recovery is to / should be excluded; the flow is diverted through a three-way valve (D). A control unit (2.8) manages the components of the hydraulic circuit through the data detected by the temperature probes (s1, s2, s3, s4, s5). There is a temperature reading system of the individual processors (2.4) which, in the event of a failure of the cooling system, disconnects the power supply to the hardware. The hydraulic circuit is completed by: the manifolds (1.11) and the delivery and return pipes (1.12), the safety valve (1.5), the expansion tank (1.6), the various shut-off valves, the pressure gauges (M) and the thermometers (T); we also find the delivery (1.14) and the return (1.13) of the user circuit.

Almost all the electrical power entering the computer is transformed into heat; about 70/80% of this heat is recovered from the storage tank in the form of hot fluid, in this case water.

The plant as described is able to perform 17.28 million hash operations per day through the calculation hardware, which correspond to a remuneration of approximately 0.014 ETH (or € 2.94 with the current value of Ethereum ); at the same time about 290 liters of water are brought from a temperature of 10 ° C to a temperature of 50 ° C.

Extending the values described on an annual basis, we have a production of:

- about 4900 thermal kWh in the form of hot fluid, sufficient to heat and produce the domestic hot water of a new building of 100 m <2> (built with the current provisions on limiting energy consumption)

- 5.11 ETH (Ethereum) in the form of a crypto-currency.

The digital currency is automatically loaded into an online wallet and can be converted into Euros according to the current exchange rate. Currently (10/2018) 1 ETH = € 198.12, so our system today would produce an annual remuneration of around € 1000. Consider that the current exchange rate is among the lowest in the last year, where it reached peaks of 1144 € / ETH; if the hypothetical user of the invented system had converted the crypto-currency produced at the moment of its maximum value, he would have collected € 5,846.

With the current exchange rate, the production of electricity through the photovoltaic system, used in a mining system such as the one in the invention, is enhanced more than in the other existing systems available.

Should the exchange rate collapse, the production of ETH crypto-currency may no longer be profitable; at this point the control PC software would automatically search for a more profitable coin on which to perform the mining (this function is already implemented in the programs in circulation). If it were not possible to find a convenient alternative block chain solution, the plant would exclude the computing hardware and proceed with selling the electricity to the grid (2.9) or using another system for self-consumption, as happens for current photovoltaic systems.

From what has been described it is evident that the instrument according to the invention achieves the intended purposes.

The object of the invention is susceptible of numerous modifications and variations, all falling within the inventive concept expressed in the attached claims. All the details can be replaced by other technically equivalent elements, and the materials can be different according to the requirements, without departing from the scope of protection of the present invention.

Although the object has been described with particular reference to the attached figures, the reference numbers used in the description and in the claims are used to improve the intelligence of the invention and do not constitute any limitation to the scope of protection claimed.

Claims (9)

Patent Application for Industrial Invention under: "COGENERATOR OF ENERGY AND CRYPT-CURRENCY" Claims 1. Cogenerator consisting of computer hardware (1.1) for the execution of mining operations (and data processing of a block chain), with a heat recovery system produced by the processors. 2. Cogenerator, according to claim 1, characterized by the fact that it simultaneously produces a physical material asset and an intangible digital asset. 3. Cogenerator, according to claim 1, characterized in that it is powered by a renewable energy source. 4. Cogenerator, according to claim 3, characterized in that it can exclude heat recovery and work for the sole purpose of enhancing electricity in the form of crypto-currency. 5. Cogenerator, according to claim 4, characterized in that it accumulates electricity, in the form of a digital asset. 6. Cogenerator, according to claim 1, characterized by a hydraulic thermal recovery system, which uses a liquid to remove heat from the processors and accumulate it in a tank in the form of a hot fluid. 7. Cogenerator, according to claims 1 and 6, characterized in that the hydraulic heat recovery system can be replaced by a refrigeration circuit which performs the same function. 8. Cogenerator, according to claims 1 and 6, characterized in that the hydraulic heat recovery system can be replaced by a series of heat pipes or pulsating heat pipes, which perform the same function. 9. System, according to claims 1 to 8, characterized by the fact that it can be reproduced in any power scale (electrical, thermal or calculation) and can be applied to any generator for which the electricity produced.